DE3711051A1 - DRIVER AND CONTROL CIRCUIT FOR LASER DIODES - Google Patents

Description

The invention relates to a driver and control circuit for laser diodes according to the preamble of the main claim.

The invention is concerned with such a gene circuit for rapid switching of a laser diode in an optical printer or the like and one High speed control of a laser diode simultaneous stabilization of an optical output signals from the laser diode.

First, the operation of a laser beam printer as the basis of the invention will be explained with reference to FIG. 14.

In Fig. 14, 101 a video signal generator, 102 a laser diode, denoted by 103 is a drive circuit and with a coupling lens 104 for forming one of the laser diode 102 output beam. A scanner motor 105 drives a polygon mirror 106 . 107 denotes an f-0 lens, and 108 denotes a photosensitive drum, the surface of which is scanned by the laser beam which is supplied via the polygon mirror 106 and the f-0 lens 107 . An image formed on the drum surface in this manner can be printed out in a manner not shown by a xerographic method.

A laser diode for use in such a laser printer has the advantage that it is small and allows direct modulation, while on the other hand, since it is a semiconductor device, it reacts critically to changes in temperature. The output signal changes significantly with temperature. Fig. 2 shows in a diagram a characteristic of the laser output signal in relation to the temperature when operating a laser diode with direct current. The optical output signal decreases with increasing temperature.

There are two factors for changing the characteristic a laser diode depending on the temperature. In the long term, there is an impact from change the ambient temperature and by an increase in temperature of the entire printer. There will be a change in the short term by self-heating of the laser diode.

The change in the characteristic due to self-heating rests on a temperature rise of a housing that the Includes laser diode. A certain remedy is through Cooling fins can be enlarged. Furthermore, the Thermal resistance between the device connection and the housing a role. A remedy is more difficult here.

Fig. 3 shows a timing diagram for illustrating the dependency of the laser printer of an expression of the temperature. The chip temperature ( b ) of the laser diode with a power supply at level "H" follows the pressure data ( a ) when switched on and off and changes exponentially. An optical output signal ( c ) is distorted with respect to the print data ( a ) due to the start characteristic of the laser and the temperature characteristic of the laser chip, which change according to the temperature, as shown in FIG. 2. The printed data ( d ) result from the assumption of a threshold value Th of the optical output signal ( c ) corresponding to the dashed line in the diagram for a xerographic printing process. In the following, the temperature characteristics and at the same time the start characteristics of the laser diode will be examined.

The aforementioned printed data ( d ) are shifted with respect to the print data ( a ), in particular due to the temperature characteristic of the optical output signal ( c ) at the start of the operation of the laser diode.

Fig. 4 (A) shows an original image corresponding to the print data ( a ) in Fig. 3, and Fig. 4 (B) shows the image obtained from the printed data ( d ) in Fig. 3 and distorted . The situation in Fig. 4 results as in Fig. 3 by scanning the figure from left to right, and when the laser diode is turned off over the positions Y 1 and Y 2 for a short period of time and then turned on as it is is shown by the scanning over an area X 1 , the lightless time corresponds to a time interval t 1 - t 2 according to FIG. 3, and the switch-off position Y 1 '(which corresponds to the time t 1 ) is essentially the same as the position Y 1 of the print data, but a subsequent switch-on position Y 2 ', which speaks the time t 2 , is delayed for a time T 1 compared to the position Y 2 of the print data. If the laser diode is switched off for a longer period of time, which corresponds to the time interval t 3 - t 4 , in which the area X 2 is scanned, and then switched on again, the switch-on position Y 4 'by a time T 2 delayed with respect to position Y 4 of the print data.

The inequality T 1 < T 2 is based on the steep rise in the optical output signal ( c ) after the longer switch-off of the laser, and the time periods T 1 and T 2 are very small, so that this change compared to the full size of the pressure is negligible is. However, the position Y 2 'is delayed by T 1 - T 2 with respect to the position Y 4 ', and this displaces the print and the print quality is impaired.

Then the frequency response of the Laser diode including the start characteristic of the Diode are described.  

In an optical printer, the maximum switching frequency f of the laser diode is expressed by the equation f = c LX LY D ² P. In this equation, LX is the lateral width of the printing paper, LY its length, D the dot density (lines / mm), P the printing speed (sheets / min.) And C a constant. However, since the speed and dot density of optical printers have been increased in recent years, a driver circuit for the laser diode is required which enables rapid switching operations. Incidentally, the waveform of the driving current of a laser diode should be substantially the same as that of the input signal in the form of an image signal, so that good print quality is achieved.

Consequently, the driver circuit, because the driver current has a square waveform, a frequency on Have speaking behavior that is sufficiently higher than the previously mentioned maximum switching frequency. Furthermore should the driver waveform stable at high speed because there is an overshoot or ringing under the Aspect of the print quality when assembling and dismantling such a waveform is not desirable.

FIGS. 15 and 16 show such known circuits. The circuit of Fig. 15 comprises a laser diode 1 which is connected to a constant current source 3 via a transistor 2 and a series circuit of a transistor 4 and a resistor 5. The transistor 4 and the resistor 5 are connected in parallel to a series circuit comprising the laser diode 1 and the transistor 2 . The transistor 4 is switched to continuity when a size L signal is received from a video signal Vin at the base of the transistor, while the transistor blocks when a size H signal is received.

The transistor 2 allows a positive potential V 2 at its base that the laser diode 1 is switched off while the transistor 4 is switched on, and that the impedance reduction takes place which is required for the laser excitation, when transistor 4 is turned off. The circuit shown in Fig. 16 is a simplification of that of Fig. 15 and enables the laser diode 1 to be energized by turning off a transistor 6 at a video signal Vin at the value L while the laser diode 1 is de-energized is due to a voltage drop across the diode in that the transistor 6 is switched on when the video signal Vin changes to the value H.

The circuit according to FIG. 15 leads to the voltage at the emitter of the transistor 2 changing rapidly, but its mode of operation is limited by the frequency characteristic of the constant current source 3 . In the same way, the circuit according to FIG. 16 has the disadvantage that the laser diode 1 is dependent on its own impedance characteristic during its transition from the emitting to the non-emitting state, which in turn is unstable because the impedance of the Laser diode 1 is sharply changed from essentially ∞ to several tens Ω at a threshold current in the diode. Otherwise, the impedance characteristic changes with the capacitance.

Now the optical output signal should be in one beam scanner, such as an optical printer or the like.

A control circuit for such an optical off gang is able to, for example, when scanning a Drum surface of the printer with an optical beam over a rotating, polygonal mirror, an opti output value of the laser diode for successive to set the pressure scans synchronously with a  Beam scan signal generated for each period and does not correspond to a picture during which the polygonal mirror after completion of the print scan one line the same operation for the next line begins to repeat.

There are some known methods for hiring one such optical output value. There is a procedure for example, in a period that is not an Ab education corresponds to an optical output value signal, which is detected by an optical detector with a Comparative value in an analog way, and that record the compared result. Another process in a digital system, the count of Im pulse within a given period or the loading completion of the counting process according to the positive or negative sign of such a comparison value and the digital-analog conversion of the result the counted value.

As the acceleration of the optical progresses Printer, however, had the timing for an optical one Output will be reduced more and more. The described above benen facilities have the significant disadvantage that they do not respond sufficiently to changes in characteristics the laser diode due to a rise in temperature Diode and the like can react because they, in particular in an analog system, are unable to control each print line as they respond slowly the comparison control and therefore the control for each Carry out the printing side. The facilities in a digi tal system have in addition to the response speed Disadvantage that changes in an optical output in insufficiently compensated for a laser diode chip, and that the number of bits of a D / A converter increases, if the amount of light in a step of a counter  is to be controlled to improve the control accuracy is reduced.

With regard to the disadvantages of the known driver and control circuits for laser diodes do it of the invention, the high-frequency characteristic of a Improve driver circuit of a laser diode.

It is intended to prevent a pressure offset due to delayed high-speed response the temperature characteristic of a laser diode occurs. Furthermore, a control circuit is to be created which the previously mentioned tasks with regard to the response speed and control accuracy for an opti output and is able to operate at high Ge speed the optical output signal at the beginning of the Control stabilize.

The solution to this problem according to the invention results from the characterizing part of the main claim.

According to a first embodiment of the invention is a provided the first switching element in series with a Laser diode is ver with a constant current source is bound so that the laser diode is actuated when is a binary driver signal at one of its values. An impedance element is parallel to the row scarf device consisting of laser diode and first switching element. The Impe danz element is with the constant current source and the laser Connected diode and has an impedance characteristic, which are essentially the same as the characteristics of the laser Is diode. A second switching element is in series with the impedance element and actuates the impedance element, when the driver signal is at the other value.

According to this embodiment, the laser diode and the like  Impedance element equivalent electrical loads, and this Alternatively, loads are switched according to the binary driver signal and with the constant current source connected. As a result, there is a reduced through gangs impedance change when switching, so that the laser Diode supplied current reversed at high speed switches and can be kept stable without a Change in potential on the load side of the constant current source occurs.

According to a second embodiment of the invention a first switching element is provided which is in series with a laser diode, which in turn is connected to a Constant current source is connected so that the laser Diode is actuated when a binary driver signal is on is one of his values. An impedance element is parallel to the series connection of laser diode and first switching element and is still in constant current source Connection to which the laser diode is also connected. An integration circuit is used to integrate the data on one of the values. An impedance control circuit for variable control of the impedance of the impedance element tet depending on the integration circuit. A second switching element is in series with the impedance element connected and serves to actuate the impedance element, when the driver signal is at the other value.

According to this embodiment, the laser diode and the like Impedance element parallel to each other with the constant current source connected so that a current alternatively through this Elements can be passed through and the impedance of the impedance element is based on the integrated Result of the data set, which results from the An drive the laser diode result. Therefore, if the impedance of the impedance element is set as such they are essentially equivalent to the impedance of the laser diode,  and the laser diode is controlled according to that Temperature rise based on the integrated result, i.e. the holding time of the switch-off phase of the laser diode. In this way, the impedance of the impedance element becomes re induced so that the voltage across the laser diode on a lower value when it is switched off. In this way, any influence of the continuation time can on the start of the laser diode when it is switched on be excluded, so that a print offset of the above described type is prevented.

According to a third embodiment of the invention is a Comparator provided that has an optical output value signal that is determined by scanning an opti output of a laser diode by recording a video signal is excited with a predetermined Comparative value compares and emits a signal that a Scale is for a relative difference between that optical signal and the comparison signal (i.e. indicates whether the optical output signal above (+) the Ver same signal or below (-) the comparison signal lies). In the following, the aforementioned signal is said to be the on referred to as a relative difference signal for the sake of simplicity will. An integration circuit is also provided, which integrates the relative difference signal. A constant current circuit for setting the current through the Laser diode flows, increases or decreases the current accordingly an integrated value of the integration circuit. A counter counts the number of reversals of the positive and negative sign of the relative difference signal over time for a given period of time. One time element causes the constant current circuit to Diode for a predetermined period in each pause Interval of the video signal drives, so that the Integra tion function of the integrator circuit is made possible and is interrupted due to the fact that the toughness  ler the count of the specified number at the end of the pre given time period or before this end.

According to this embodiment, the optical output value signal in phase with the optical output signal of the laser diode delayed. This allows the opti cal output value signal, which is input into the comparator will go slightly beyond the comparison value signal and fall under it and then rise again and drop off without comparing in the breaks of the video signal to stop. The counter can be on it towards the number of ascent and descent of the optical off gangswertsignal with respect to the comparison value signal tough len and based on the fact that this number is one has reached a predetermined value, a current value of the con Hold the constant current circuit over the next printing period. In this way the optical output of the laser diode set to a value that changes in a given time after stabilization results.

Preferred embodiments of the Invention together with some details of the prior art the technology with reference to the accompanying drawing he purifies.

Fig. 1 shows a driver circuit for a laser diode according to an embodiment of the invention;

Fig. 2 is a temperature-dependent diagram of the optical output signal of a laser diode;

Fig. 3 is a timing chart for illustrating the temperature dependency of the printed output signal in a laser beam printer;

Figs. (A) and (B) are views of the printing result which is staggered due to the characteristic of Fig. 3;

Fig. 5 is a timing diagram illustrating the desired operation according to the invention according to Figs. 1 and 3;

Fig. 6 is a timing diagram illustrating the operation of the circuit of Fig. 1;

Fig. 7 is a block diagram showing a driver circuit as an embodiment of the invention;

Fig. 8 is a block diagram of an optical output controller as an embodiment of the invention;

Fig. 9 illustrates the operation of Fig. 8 in a timing diagram;

Fig. 10 shows the operating characteristic of the integration circuit when a power source is turned on;

Fig. 11 is a block diagram of an optical output control circuit according to another embodiment of the invention;

Fig. 12 illustrates in a timing diagram the operation of the parts of Fig. 11;

Fig. 13 shows the operating characteristics of the integration circuit when the power source is turned on;

Fig. 14 illustrates the principles of operation of a laser printer;

Fig. 15 is a block diagram showing a known driver circuit;

Fig. 16 also shows a known driver circuit in a simplified form.

Details of the first, second and third will now be given Embodiment of the invention explained with reference to the drawing will.

Fig. 1 and 7 show circuit diagrams of the driver circuit for a laser diode as the first and second embodiment of the invention. The same reference numbers are used for corresponding parts. As far as the individual embodiments overlap, repetitions in the explanation should be avoided. Occasionally, therefore, the reference numerals of the parts of the second embodiment are put in parentheses after those of the first embodiment.

In FIG. 7, 1 (102) is a laser diode, 3 (109) is a constant current source, 7 (110) is a transistor which serves as the first switching element, 8 (111) is a transistor which is an impedance element, and 9 (112) denotes a transistor which is a second switching element. The laser diode 1 is connected to the constant current source 3 , and the transistor 7 is connected in series with the laser diode 1 . The transistor 7 further receives a video signal Vin (print data ( a )) at its base via an inverter 10 , which is missing in the second embodiment, and is switched to continuity when the video signal Vin (print data ( a )) on the Value L is (H value), so that the laser diode 1 ( 102 ) is energized while the transistor 7 is blocked when the video signal Vin is at the value H (L) at which the laser diode 1 ( 102 ) is switched off. The transistor 8 ( 111 ) is parallel to the laser diode 1 ( 102 ) and takes the current from the constant current source 3 ( 109 ) together with the laser diode. The transistor is set by a constant voltage V 1 to a substantially the same impedance characteristic as the laser diode 1 ( 102 ). In the second embodiment, the constant voltage V 1 is absent, and the impedance characteristic of the transistor 8 is set to the impedance characteristic of the laser diode 102 in a manner described later. Then a voltage drop of the transistor 8 ( 111 ) is set to 1.8 V during its operation, for example. This value corresponds essentially to that of laser diode 1 ( 102 ) during its operation. transistor 9 ( 112 ), which is arranged in pairs with transistor 7 ( 110 ) and is selected to have the same characteristics as transistor 7 ( 110 ), is connected in series with transistor 8 ( 111 ). The transistor 8 ( 111 ) continues to receive the video signal Vin (print data ( a )) directly at its base via the inverter 113 and is switched to pass when the video signal Vin (print data ( a )) is at the H value, so that transistor 8 ( 111 ) as a load of constant current source 3 ( 109 ) is then energized while being turned off when video signal Vin (print data ( a )) is at L (H) and transistor 8 ( 111 ) is then switched off. Accordingly, the resistors 11 , 12 ( 114, 115 ) serve to bring the transistors 7 , 9 ( 110, 112 ) into their active state and to accelerate their response to the video signal Vin (print data ( a )).

With this arrangement according to the first embodiment of the invention, when the square wave of the video signal Vin is H , the transistor 7 is turned off and the transistor 9 is turned on, and consequently a constant current from the constant current source 3 passes through the transistor 8 . When the video signal Vin is L , the transistor 7 is turned on and the transistor 9 is turned off, so that the current flow through the transistor 8 is interrupted. At the same time, a constant current flows through the laser diode 1 instead of the transistor. In this way, the transistor 8 and the laser diode 1 are switched as loads, so that they are al ternatively in operation without generating voltage changes on the load side of the constant current source 3 .

In the circuit shown in Fig. 7, an impedance element instead of the transistor 8 by a number of diodes in series connection are formed.

With regard to the second embodiment, this is ahead add the following description.

In Fig. 1, 116 denotes a bias circuit which is used for impedance control. Unless the impedance of transistor 111 is controlled by this bias circuit 106 to match that of laser diode 102 , a potential at point ( a ) in alternative operation of transistors 110 and 112 is prevented from being changed due to the print data . Therefore, the current that alternatively flows through transistors 110 and 112 remains substantially constant during the rapid switching.

If the lightless time of the laser diode according to FIG. 3 is longer, as previously described, the optical output signal of the laser is built up steeply when it is switched on. If the lightless time is shorter, the construction time of the current i flowing through the laser didoe 102 is steeper due to the decrease in the impedance reduction of the transistor 111 during the lightless time of the laser, ie during the operation of the transistor 111 . As a result, the potential at point h is relatively raised, as shown in FIG. 5, while when the laser is idle for a longer period of time, the current i builds up more slowly because the impedance decrease increases and the potential at point h decreases. In this way, the expansion behavior of the two optical output signals is preferably made comparable.

Denoted at 117 is an integration circuit that receives the print data ( a ) and delivers an integrated result ( e ) that relates to a characteristic that corresponds to the chip temperature ( b ). A comparator 118 compares the integrated value e with a predetermined reference potential VR and outputs an output signal ( f ) from the potential H if the former value is higher than the latter, and an output signal ( f ) from the potential L if the former value is less than the latter. 119 denotes an OR circuit which receives the output signal ( f ) of the comparator 118 and the print data ( a ) and forms a logical sum ( g ). The bias circuit 116 is controlled by a binary value based on this sum ( g ). When the sum ( g ) is at the potential H , the laser is often energized and emits light, while the transistor 111 has high impedance in each case of the operation and the non-operation of the transistor 112 , so that the value H is high Potential is so that the current profile i is steep. When the sum ( g ) is at the potential L , the transistor 111 has a low impedance when the transistor 112 is in operation, since the sum ( g ) at the value L is caused by a longer lightless time. Therefore, the point ( h ) has a low potential, so that the current build-up is smoother. In this way, the construction characteristics of the optical output signal ( c in Fig. 3) are corrected by the current i (see Fig. I in Fig. 5), and the pressure offset due to the temperature change of the laser diode 102 becomes short corrected.

Referring to FIG. 6 is to be assumed that the comparison potential VR is constant and that the sum (g) for the control of the bias circuit 116 is a binary value. This is generally sufficient, but it is also possible if a finer resolution is desired to provide a number of comparators 118 and a number of Poten tialen VR used for controlling the bias circuit 116 at different levels.

If the integrated value ( e ) is converted using amplifiers instead of the comparator 118 in Fig. 1, and for example the maximum value which has been converted in height in this way corresponds to the potential H of the print data ( a ), and if both values are further added using a sum circuit instead of the OR circuit 119 , the bias circuit 116 is controlled while taking the minimum values of the curve ( e ) in Fig. 6 into account even if the laser diode is included high accuracy is started.

Subsequently, details of the third embodiment of the invention will be described with reference to FIGS. 8, 9 and 10.

Fig. 8 is a block diagram of the control circuit of the optical output signal in a first form of the third embodiment, and Fig. 9 is a timing chart for illustrating the operations of each part of the control circuit.

With 201 a laser diode arrangement is designated, which receives a laser diode 202 and a photodiode. A constant current circuit 204 provides a constant current that flows through the laser diode 202 . A transistor 205 controls the switching on and off of the laser diode 202 accordingly in accordance with a light emission control signal, which is supplied via a non-or gate 206 . A signal ( j ) is a line start pulse signal that sets a period TO for printing over a line. A timer 207 is used to set the printing interval. Its output signal ( k ) sets a pressure interval T 1 using the signal ( j ) as a starting point. A timer 208 is used to set a test interval. An output signal ( l ) of this timer sets the maximum value T 2 of an integration interval described later in a print pause using the end point of the pressure interval Tl as a starting point. A signal ( m ) is a video signal, the high (H) potential of which corresponds to white and the low (L) potential of which corresponds to black, with reference to FIG. 9. The aforementioned signal ( 1 ) is found at the L potential in the Print interval Tl and triggers the video signal ( m ) for transistor 205 . The signal ( 1 ) is at the potential H in the interval T 2 and, independently of the video signal ( m ), causes the transistor 205 to control the laser diode 202 for its light emission. A signal ( s ) is an optical output value signal, ie an electrical signal, which it is aimed at by scanning the optical output of laser diode 202 using photodiode 203 , the signal of which is proportional to the optical output of laser diode 202 with some delay will be changed. The photo diode 203 is then reverse biased by a negative electrode E 1 . A comparator is designated by 209 , which receives a positive potential Vr with respect to a current source El as a comparison value and emits an H signal when the optical output value signal ( s ) exceeds the potential Vr . Also indicated at 210 is a counter which counts the set-up signal by which the comparator 209 changes the H value and changes the output signal ( I ) of the timer 208 to the value L when reading the predetermined number if the control is within the interval T 2 lies. With 211 , an integration circuit is referred to, the states as an operational amplifier against R 1 and R 2 and a capacitor C 1 etc. includes. The circuit integrates the output signal corresponding to a positive or negative value of the output signal when the output signal of the comparator 209 is received . With 213 an analog switch is designated, the contact S 1 is open and the contact S 2 is closed when the output signal ( 1 ) of the timer 208 rises to the value L and which holds the output of the integration circuit 211 . On the other hand, the contact S 1 is closed and the contact S 2 ge opens when the output signal ( 1 ) is at the potential H , so that the integration circuit can receive the output signal of the comparator 209 for its integration. The constant current circuit 204 receives the output signal of the integration circuit 211 at the base of a first-stage transistor 214 with high impedance and keeps this output signal substantially constant during the printing interval of a line. The transistor 214 receives a positive voltage V 2 and a negative voltage E 1 at its terminals, so that it is set in this way to a constant current according to the output signal of the integration circuit 211 . A second stage transistor 215 takes the current flowing through the transistor 214 , thereby setting the laser diode 202 connected to the transistor 214 as a load of the constant current source according to the output of the integration circuit 211 .

Then the operation of the control circuit of the optical output signal of the third embodiment of the Invention are described.  

In the pressure interval P 1 , the output signal ( 1 ) of the timing element 208 is at the potential L , while the analog switch 213 is open at its contact S 1 and closed at its contact S 2 , as shown in FIG. 8. The integration circuit 211 is in its standby position. The non-or gate 206 triggers the video signal ( m ), by which the laser diode 202 is controlled in its light emission. The photodiode 203 scans the output of the laser diode 202 . Although the output optical value signal ( s ) is changed, it is not used because the contact S 1 is open at this time.

When the printing of a line has ended and the signal ( l ) assumes the H potential, the contact S 1 is closed and the contact S 2 is opened, so that the integration circuit 211 begins with the integration of the output signal of the comparator 209 . At the same time, the laser diode 202 is driven by the set current of the constant current circuit 204 independently of the video signal ( m ). The photodiode 203 scans the optical output of the laser diode 202 , and the optical output value signal ( s ) is raised, for example. When the optical output signal (n) is lower than the reference value Vr, it enables the integration circuit 211 is that the inte grated value is increased, so that the optical output can be increased, the laser diode 202nd When the optical output value signal ( s ) assumes the H potential, the counter 210 is allowed to count the structure of the output signal of the comparator 209 . The integration circuit device 211 reduces the integrated value, so that the laser diode 202 can also lower its output. In this way, the reduction of the optical output signal ( s ) begins. By repeating this process, the optical output signal of the laser diode 202 reaches its stable state since the temperature of the laser diode 202 becomes constant and the optical output value signal ( s ) fluctuates slightly around the value Vr . When the counter 210 has reached the predetermined number, the signal of the timing element 218 changes to the potential 1 , while the contact S 1 is open and the contact S 2 is closed. In this way, the integration circuit 211 holds its integrated value at this time, so that the current flows through the laser diode 202 in a subsequent printing interval T 1 that is to be set.

Fig. 10 illustrates the change in the state of the constant current circuit 204 in dependence on the integration value of the integration circuit 211 at the time when the control current source is switched on in accordance with the repetition period TO of printing. The build-up of the rotation of the rotatable polygonal mirror when the power source is switched on requires a certain time, so that the counter 210 does not count in an interval from the time when the power supply is switched on until the point in time t 1 when this speed build-up is essentially completed. The integration circuit 211 integrates over the entire interval T 2 , which is set by the timer 208 . When a normal operating state is reached, the counter 210 determines a reduced time in the interval T 2 . The time constant of the integration circuit, which is determined by the resistors R 1 and R 2 and the capacitor C 1 etc., relates to slight changes in the signal ( s ) in the vicinity of the comparison value Vr and can be relatively small, so that the accuracy the optical output signal is improved ver.

Another embodiment of the optical output control circuit will be described below in connection with FIGS. 11, 12 and 13. This embodiment corresponds essentially to the previous one, but a non-and gate 216 (if the line start signal P is assumed negative) and a flip-flop 217 for setting the test interval are added or exchanged (the flip-flop 217 replaces this timer 208 of FIG. 8) between the timer and the counter 210 shown in FIG 8. in this manner, the temporal relationship in the catch on the control time improved. If the line start signal P is positive, an OR gate is used instead of the non-AND gate.

The operation of this embodiment corresponds in the we substantial of the preceding, so that only the sub differences and advantages should be described.

The flip-flop 217 is set so that the laser diode 202 is driven by the set current of the constant current circuit 204 depending on the integrated value of the integration circuit 211 and independently of the video signal S. When the integrated value reaches a constant value at time t 1 , the signal ( t ) reaches the potential Vr , as shown in Fig. 12, so that the counter 210 can start counting. When a predetermined count is reached at time t 2 , the flip-flop 217 is set, and then the above-mentioned stationary control is performed.

As previously explained, according to the first embodiment Form of the invention from a constant current source Current of the same load in operation and outside of the Operation of the laser diode supplied, so that the Potential on the load side of the constant current source is not changes and the laser diode at rapid speed can be switched. It is therefore suitable for ver high speed and different optical printers high density. The corresponding circuit can be found in easily realized by adding some switching elements the known switching elements are added.  

According to the second embodiment of the invention, the Laser diode and the impedance element with the constant current source connected, and the impedance of the impedance element is set and controlled based on the inte gration of data resulting from the operation of the laser diode surrender. When this data is related to the temperature characteristics of the chip of the laser diode, it is possible to build the optical characteristics Output signal based on the interval of lightless time to be used for temperature compensation. So there is no shift of the printed image according to the number switching on the light of the laser diode during printing, so that the print quality is improved. According to the third embodiment of the invention is a comparator provided the repeated minor changes to the Samples the value of the constant current, which with the help of Integration circuit is set so that by a predetermined count can be checked whether the change reached a predetermined value. Consequently, it is high speed operation with a simple arrangement ensured and every error that occurs due to noise when scanning can also be corrected. Every change of the op table output signal of the laser diode and changes the characteristic of the diode due to the temperature taken into account in the count, so that one is the same visual control. Also at the start the control, the laser diode and the integration circuit continuously in operation until the optical output value the laser diode reaches the comparison value, so that the optical output can be quickly set up and stabilized can. The device according to the invention is independent adjustable as an optical scanning unit that is easy to take under hold is.

Claims (13)

1. Driver and control circuit for laser diodes, characterized by

• (a) a first switching element ( 7 ) connected in series with a laser diode ( 1 ), which in turn is connected to a constant current source ( 3 ) which actuates the laser diode when a binary drive signal is at one of its potentials,
• (b) an impedance signal ( 8 ) in parallel connection to the series circuit comprising the laser diode and the first switching element, which impedance element is connected together with the laser diode to the constant current source and has an impedance characteristic which essentially corresponds to that of the laser diode, and
• (c) a second switching element ( 9 ) in series connection with the impedance element for actuating the impedance element when the drive signal is at its other potential.

2. Circuit according to claim 1, characterized in that the first switching element ( 7 ), the impedance element ( 8 ) and the second switching element ( 9 ) are transistors. 3. A circuit according to claim 1, characterized in that the first and second Schaltelemen te ( 7, 9 ) are arranged in pairs to each other and have the same characteristic. 4. Circuit according to one of the preceding claims, characterized in that the impedance element ( 8 ) consists of a number of diodes connected in series. 5. Driver and control circuit for laser diodes, characterized by

• (a) a first switching element ( 110 ) connected in series with a laser diode ( 102 ) which in turn is connected to a constant current source ( 109 ) which actuates the laser diode when a binary drive signal is at one of its potentials,
• (b) an impedance element ( 111 ) connected in parallel to the series circuit comprising the laser diode and the first switching element, which is further connected together with the laser diode to the constant current source ( 109 ),
• (c) an integration circuit ( 117 ) for integrating the data at one of the potentials,
• (d) an impedance controller for adjusting the impedance of the impedance element in accordance with the integrated data,
• (e) a second switching element ( 112 ) connected in series with the impedance element ( 111 ) to actuate it when the drive signal is at its second potential.

6. A circuit according to claim 5, characterized in that the first switching element ( 110 ), the second switching element ( 112 ) and the impedance element ( 111 ) are transistors. 7. Circuit according to claim 5 or 6, characterized in that the first and second switching element ( 110 , 112 ) are arranged in pairs and have the same characteristics. 8. Circuit according to one of claims 5 to 7, characterized in that the impedance control is a bias circuit ( 116 ). 9. Circuit according to one of claims 5 to 8, characterized in that a comparator ( 118 ) is seen before. 10. Circuit according to claim 9, characterized through several comparators. 11. Driver and control circuit for laser diodes, characterized by

• (a) a comparator ( 209 ) for comparing the optical output value signal at the optical output of the laser diode ( 201 ), which is excited by recording a video signal, with a comparison value and for emitting a signal corresponding to the relative difference between the optical signal and the comparison value,
• (b) an integration circuit ( 211 ) for integrating the relative difference signal,
• (c) a constant current circuit ( 204 ) for adjusting the current flowing through the laser diode by increasing or decreasing the current according to the integrated value of the integration circuit,
• (d) a counter ( 210 ) for counting the inversions of the positive or negative sign of the relative difference signal with the lapse of time over a predetermined period of time, and
• (e) a timer ( 207 ) which causes the constant current circuit ( 204 ) to operate the laser diode for a predetermined time in each pause interval of a video signal, to trigger the integration function of the integration circuit and interrupt it according to the count by the counter on End of or before the specified period.

12. Circuit according to claim 11, characterized records that the integration circuit is an Opera tion amplifier, resistors and capacitors. 13. Circuit according to claim 11 or 12, characterized ge indicates that the timer is a flip-flop and that a timing control terminal is provided which it allows a non-and gate or an or gate between to arrange the flip-flop and the signal input terminal.